System and method for detecting a breach of an electronic article surveillance tag

ABSTRACT

An EAS tag is provided having improved anti-defeat devices and methods. A pin assembly is coupled to a lanyard and includes a reduced cross-sectional profile that may be passed through a monitored article to produce no damage or minimal damage to the monitored article. The pin assembly engages a spring clamp provided in the EAS tag and is electrically coupled to an intermediate spring contact that provides an electrical current to a PC board for arming the EAS tag. A force may be applied to the intermediate spring contact to generate a reset signal that disarms the EAS tag. An alarm signal is generated if current to the PC board is disrupted without a corresponding reset signal, such as if the pin assembly is removed without rotating the intermediate spring contact or if the lanyard is cut. The tag body is provided with an arcuate channel through which an arcuate detacher probe can be guided for releasing the attaching assembly part.

CROSS-REFERENCE TO RELATED APPLICATION

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STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

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FIELD OF THE INVENTION

This invention relates to electronic article surveillance (“EAS”) tags,and in particular to EAS tags having anti-defeat mechanisms.

BACKGROUND OF THE INVENTION

Electronic article surveillance systems are used for inventory controland to prevent theft or unauthorized removal of articles from acontrolled area. The EAS systems include transmitters, receivers, andEAS tags. Typically, the transmitters and the receivers are positionedat entry/exit points of the controlled area and the EAS tags are affixedto articles that are located within the controlled area. The EAS tagsinclude a marker or a sensor that receives the transmitter signals andgenerates a response signal that is detected by the receiver. The EASsystem generates an alert signal when the response signal is detectedwithin a predefined distance of the receiver.

A variety of EAS tags exist, including multi-use EAS tags and disposableEAS tags. The multi-use EAS tags include releasable attachment devicesfor affixing the tags to the monitored articles. The attachment devicesare designed to be releasable by authorized personnel. EAS tags aredesigned to minimize unauthorized removal of the EAS tags from monitoredarticles. Typically, attachment devices are releasable only through theuse of an associated special tool or detaching mechanism. By contrast,disposable EAS tags are permanently affixed to the monitored articlesand are deactivated by authorized personnel prior to removal from thecontrolled area.

U.S. Pat. No. 6,535,130 (the '130 patent), entitled Security Apparatusfor Electronic Article Surveillance Tag, the disclosure of which isincorporated herein by reference, discloses multi-use EAS tags that arereleasable from monitored articles. The release mechanism is a detacherdevice having an arcuate probe that is inserted into an arcuate channelof the tag and contacts a spring clamp mechanism. The spring clampmechanism is a releasable locking mechanism that captures a tackassembly that is inserted into an opening in the tag body.

FIG. 1 illustrates a conventional EAS tag 100 disclosed in the '130patent. The EAS tag 100 includes a lanyard 102 that attaches around orthrough a portion of a monitored article. A loop 103 is provided on oneend of the lanyard 102 to secure the lanyard 102 to the body of the EAStag 100 using a tack head 104A. As illustrated, the lanyard 102 isplaced through a slit 105 and the loop 103 is positioned within arecessed area 106. A tack body 104B passes through the loop 103 andinserts into an opening 107 in the EAS tag 100. The tack assembly 104 isreleasable from the EAS tag 100.

Existing EAS tags secure one end of the lanyard to the EAS tag housingand use a separate tack structure to secure the lanyard loop against theEAS tag housing. The lanyard provides one mechanical connection point tothe EAS tag. What is needed is an EAS tag having a lanyard with twomechanical connection points so that current can be directed through thelanyard to provide a break detection circuit.

Additionally, existing EAS tags include loop dimensions that are muchlarger than the lanyard diameter and therefore define the opening sizethat is able to receive the lanyard. The separate tacks have bulky headsto prevent the lanyard loop from slipping over the tack head. Theseparate tacks are easily misplaced, which causes unnecessaryfrustration to users and replacement costs. What is needed is an EAS tagthat is not readily defeatable and which does not include a lanyard loopor a separate tack arrangement.

SUMMARY OF THE INVENTION

The invention advantageously provides a method and system for providinga break detection circuit that employs a lanyard with two mechanicalconnection points that enables current to pass through the lanyard. Inaccordance with one embodiment, the present invention provides anelectronic article surveillance (EAS) tag that includes a tag bodydefining an interior and having an opening leading into the interior. Acircuit board is disposed in the tag body interior. The EAS tag includesa lanyard having a first end and a second end opposite the first end,where the first end is electrically coupled to the circuit board. A pinbody is electrically coupled to the second end of the lanyard, and isinsertable into the tag body opening. A clamp is disposed in the tagbody interior and is adapted to receive the pin body. A spring contactis disposed in the tag body. The spring contact is electrically coupledto the clamp and the circuit board to provide a current path forelectrical signals.

In accordance with another aspect, the present invention provides amethod of securing an electronic article surveillance (EAS) tag to anarticle. The EAS tag includes a tag body defining a tag body interiorand an alarm disposed in a tag body interior. The EAS tag furtherincludes an electrically conductive lanyard having a first end and asecond end opposite the first end. The first end is fixedly coupled andelectrically coupled to a circuit board provided in the tag bodyinterior. The second end is coupled to a pin body. The pin body iselectrically couplable to the circuit board. The tag body further housesa clamp to mechanically lock the pin body at last partially inside thetag body. The lanyard is attached to the article by one of inserting thelanyard through an opening in the article and wrapping the lanyardaround at least a portion of the article.

The pin body is inserted into the tag body interior. A force is appliedto the pin body to cause the pin body to lock into the clamp in the tagbody interior. The tag body interior further includes a spring contactto electrically couple the clamp to the circuit board to create a enablea current to flow from the circuit board, through the lanyard, the clampand the spring contact before returning to the circuit board.

According to another embodiment, an electronic article surveillance(EAS) tag is provided and includes a tag body that defines an interiorhaving an opening that leads into the interior of the tag body and alanyard mounting structure that is coupled to the tag body. The securingdevice includes a lanyard having a first end and a second end oppositethe first end. The first end is coupled to the lanyard mountingstructure in the tag body interior. The securing device further includesa fastener that is coupled to the second end of the lanyard and a pinassembly that is coupled to the fastener. The lanyard, the fastener andthe pin assembly have substantially equivalent cross-sectional profiles.The substantially equivalent cross-sectional profiles facilitatethreading the lanyard, the fastener and the pin assembly through smallopenings.

BRIEF DESCRIPTION OF THE DRAWINGS

A more complete understanding of the present invention, and theattendant advantages and features thereof, will be more readilyunderstood by reference to the following detailed description whenconsidered in conjunction with the accompanying drawings wherein:

FIG. 1 illustrates a conventional EAS tag;

FIG. 2 illustrates a view of the exterior of a EAS tag according to oneembodiment of the invention;

FIG. 3 illustrates a view of the interior of a EAS tag according to oneembodiment of the invention;

FIG. 4 illustrates a view of the interior of the upper housing of a EAStag according to one embodiment of the invention;

FIG. 5 illustrates an exploded view of the spring clamp and anintermediate spring contact used in the EAS tag of FIG. 3;

FIG. 6 illustrates a partial views of the interior of the lower housingof the EAS tag of FIG. 2 with the probe inserted in the arcuate channelof the EAS tag;

FIG. 7 illustrates an exploded view of a spring clamp and anintermediate spring contact positioned in the EAS tag of FIG. 2according to one embodiment of the invention;

FIG. 8 illustrates an exploded view of a first orientation between anintermediate spring contact and a circuit board according to oneembodiment of the invention;

FIG. 9 illustrates an exploded view of a second orientation between anintermediate spring contact and a circuit board according to oneembodiment of the invention;

FIG. 10 illustrates a block diagram of one embodiment of the tag alarmaccording to one embodiment of the invention; and

FIG. 11 illustrates a flow chart of the tag alarm switch logic accordingto one embodiment of the invention.

DETAILED DESCRIPTION OF THE INVENTION

Before describing in detail exemplary embodiments that are in accordancewith the present invention, it is noted that like reference designatorsrefer to like elements. Referring now to the figures, as used herein,relational terms, such as “first” and “second,” “top” and “bottom,” andthe like, may be used solely to distinguish one entity or element fromanother entity or element without necessarily requiring or implying anyphysical or logical relationship or order between such entities orelements. The terms “upper” and “lower” refer only to the orientation ofthe EAS tag and are not structural limitations.

FIG. 2 illustrates a tag 1 that includes an upper housing 2 having sidewalls 2A, 2B, 2C and 2D that are joined by a top wall 2E. The EAS tag 1also includes a lower housing 3 having side walls 3A, 3B, 3C and 3D thatare joined by a bottom wall 3E. The upper and lower housings 2 and 3 arejoined or mated along corresponding or associated side wall pairs (2A,3A), (2B, 3B), (2C, 3C) and (2D, 3D) to form a closed tag body 1Adefining an interior. The housings 2 and 3 are preferably made of a hardor rigid material such as, for example, an injection molded ABS plastic.If a plastic is used, the mating side walls of the housings can bejoined by an ultrasonic weld 1B or like joining mechanism. A lanyard 134is mechanically and electrically coupled to an alarming device. Thelanyard 134 includes a pin assembly 304 at one end portion that ismechanically coupled with a fastener 302. The pin assembly 304 includesa pin body 306, a circumferential groove 308 and a pointed end 310.

Referring to FIGS. 3 and 4, the inner surfaces 2F and 3F of the walls 2Eand 3E of the housings 2 and 3 are provided with frame members 2G and 3Gwhich together define an interior cavity 1C for receiving an EAS sensor5. The EAS sensor 5 can be any sensor that generates detectable EASsignals, and may be an acoustically or mechanically resonant magneticsensor. An arcuate channel 7 is defined by a curved inner wall 7A. Thiswall extends upward from the inner surface of the bottom housing 3 toabut the inner surface 2F of the upper housing 2. The wall 7A is furtherspaced from the side wall 3D of the bottom housing 3 and its outward end7A′ terminates at an inward curved part 3A′ of the side wall 3A. Theinward curved part 3A′ of the wall 3A results in a space or slot 9Adefined between the side walls 3A and 3D of the lower housing 3. Theupper housing 2 includes an opening 40 for the lanyard 134. The lanyard134 includes a pin assembly 304 at one end portion that is mechanicallycoupled with a fastener 302. The pin assembly 304 includes a pin body306, a circumferential groove 308 and a pointed end 310.

The slot 9A cooperates with a similar slot 9B between the side walls 2Aand 2D of the upper housing 2 to define a second opening 9 for providingentry or access into the outward end 7′ of the channel 7. At this entrypoint, the side wall 2A also curves inwardly at a part 2A′, the latterpart 2A′ mating with the curved side wall part 3A′ of the side wall 3 ofthe lower housing 3.

The channel 7 is further defined by a second curved wall 7B of FIG. 4that extends downwardly from the inner surface 2F of the upper housing2. The wall 7B is situated outward of the inner end 7A″ of the curvedwall 7A and extends beyond this end to the frame member 2G.

FIG. 5 illustrates a conventional locking member 6 that is providedwithin the tag body 1A for releasably preventing a pin body 306 frombeing withdrawn from the tag body. The pin assembly 304 and themonitored article 51 thus become releasably locked to the EAS tag 1 bythe locking member 6. The EAS tag 1 is designed so that access to thelocking member 6 for releasing the pin assembly 304 is made difficultfor other than authorized personnel. For example, the tag body 1A isconfigured so that access to the locking member 6 is through an arcuatechannel 7 defined by one or more inner walls and by parts of the sidewalls and upper and lower walls of the tag body 1A. With thisconfiguration, a special arcuate probe 8 is needed to reach and releasethe locking member 6 to detach the pin assembly 304 and the article fromthe tag body 1A. The configuration of the channel 7 changes at its innerend 7″ to define a keyway for the channel 7 which receives the probe 8that passes through the channel 7 to gain access to the locking member6. For example, the channel cross section may change from substantiallyrectangular to substantially L-shaped.

FIG. 6 is an enlarged view of the section of the lower housing 3containing the locking member 6 and the arcuate channel 7. The arcuateprobe 8 is shown as received in and guided by the channel 7 to thelocking member 6 for the purpose of releasing same. The forward end 8Aof probe 8 is L-shaped and, thus, fits within the L-shaped keywaydefined by inner end 7″ of the channel.

Adjacent the inner end 7″ of the channel 7, the lower and upper housings2 and 3 are provided with further curved walls 9 and 11 that terminatein wall sections 9A and 11A abutting the end walls 2D and 3D. The walls9 and 11 are positioned outward of the channel 7 and, with the end walls2D and 3D, define a trap area 13, which prevents access to the member 6.This area provides a safety measure for blocking unauthorized objectsthat may be introduced into the channel 7 of the tag body 1A in anattempt reach the locking member 6.

The locking member 6 is provided to releasably prevent the pin body 306from being withdrawn from the tag body 1A. More particularly, thelocking member 6 is adapted to accommodate release of the pin body 306via the arcuate probe 8 that travels down the arcuate channel 7. Thelocking member 6 is shown in detail in FIG. 6 and in an exploded view inFIG. 5.

The locking member 6 maybe a spring clamp having a clamp body 14 andjaws 15, 16. The clamp body includes a mounting part 14A extendinglaterally of the jaw 15 and a release part 14B extending laterally ofthe jaw 16. The mounting part 14A includes a mounting aperture 14A′. Thejaws 15, 16 extend outwardly of the plane defined by the clamp body 14and then extend inwardly toward the other jaw. The jaws 15, 16 terminatein facing edges 15A and 16A. These edges extend from a common edge 14Cof the clamp body 14 inwardly toward each other, then curve outwardlyaway from each other to define an aperture 14C′ (typically, circular orelliptical) for receiving the pin body 306. The edges 15A and 16A thencontinue in aligned fashion and end in an elongated, lateral slot 14D inthe clamp body 14. The latter slot lies inward of a further clamp bodyedge 14E, which opposes the clamp body edge 14C.

A further laterally extending elongated spring sleeve or arm 17 isattached to the clamp body 14 by a joint area 18 located on the side14E′ of the edge 14E that borders the mounting part 14A. The sleeve 17extends along the length of the edge 14E and is provided outside theplane defined by the clamp body 14.

Referring to FIG. 3, the lower housing 3 of the tag body 1A includes ahollow circular mount 21 with a lip 21A and support walls 22, 23 and 24to mount and support the spring clamp 14. The clamp is mounted, via theaperture 14A′ of the mounting part 14, on the mount 21 with the area ofmounting part adjoining the aperture 14A′ supported on the lip 21A. Acircular wall 25 of the upper housing 3 and a central cylindrical stud26 of this housing (see FIG. 4) maintain the mounting part 14A in itsmounted position, while allowing the mounting part to be rotated. Thespring clamp 14 therefore pivots about the mounting part.

The back end 14A″ (shown in FIG. 5) of the mounting part 14A and thelateral part of the spring clamp 14 that connect the mounting part 14Aand the release part 14B are supported on the support walls 22 and 24,while the release part is carried by the wall 23. The spring sleeve 17rests with one end 17A in a slot 24A in the support wall 24.

The pointed end 310 of the pin body 306 is introduced in the downwarddirection through the opening 124 in the upper housing 2 and into theaperture 14C′ defined by the facing edges 15A, 16A of the jaws. Thiscauses the jaws to spread or open and allow the pin body 306 to passthrough the jaws. When the downward travel of the pin body 306 isstopped at a desired circumferential groove 308, the jaws 15, 16 retractand clutch the pin body 306. In this position, the jaws 15, 16 preventupward movement of the pin assembly 304.

The arcuate probe 8 is introduced into the opening of the tag body 1A(as shown in FIG. 2) to release the pin assembly 304 from the tag body1A via rotation of the probe about its rearward end 8B. This causes thearcuate probe 8 to move into and be guided by the channel 7 until theL-shaped forward end 8A of the arcuate probe 8 reaches and passes intothe L-shaped inner end 7″ of the channel 7. This brings the probe end 8Ato the part of the common edge 14C that borders the release part 14B ofthe clamp body 14.

By applying continued pressure on the arcuate probe 8, a force isapplied on the release part 14B of the clamp body 14. This applied forcecauses the clamp body 14 to rotate about the support area 14A on themount 21 and causes the jaws 15, 16 to spread apart. The aperture 14C′expands to release the pin body 306 from the grip or clutch of the jaws15, 16. The pin assembly 304 moves in an upward direction to withdrawand separate from the tag body 1A.

During rotation of the clamp body 14 from the in-plane force exerted bythe probe 8, the spring arm 17 is compressed at the joint 18. After thepin assembly 304 separates from the tag body 1A, the arcuate probe 8 isdisengaged from the release part 14A of the spring clamp 14 as thearcuate probe 8 is withdrawn from the channel 7. With the force on thespring clamp 14 removed, the spring arm 17 expands. This causes thespring clamp 14 to rotate in an opposite direction about the supportarea 14A. The spring clamp 14 is brought back to its original positionawaiting reentry of the pin body 306.

Referring again to FIG. 3, the EAS tag 1 is illustrated incorporatingthe anti-defeat embodiments of the present invention. A pin assembly 304may be provided at an end portion of the lanyard 134 to mechanically andelectrically couple the lanyard 134 to an alarming device. A clip 301may be provided at a second end portion of the lanyard 134 to secure thelanyard 134 to the circuit board 110. According to one embodiment, thepin assembly 304 may include cross-sectional dimensions that aresubstantially similar to cross-sectional dimensions of the lanyard 134.For example, the pin assembly 304 may include a circumferentialcross-section that is substantially similar to a circumferentialcross-section of the lanyard 134. The pin assembly 304 may be formedinto one of several shapes for insertion into aperture 124. For example,the pin assembly 304 may be formed in a curvilinear shape or a linearshape, including a rod shape, a hook shape or other shapes.

The pin assembly 304 may include a pin body 306 having one or more slotsor circumferential grooves 308 that latch into the spring clamp 14 and apin tip 310. The pin assembly 304 may be integrally formed with thelanyard 134. Alternatively, the pin assembly 304 may be formedseparately from the lanyard 134 and may be coupled to the lanyard 134.The pin assembly 304 may be electrically and mechanically coupled to thelanyard 134 using a fastener, such as a ferrule 302 or other fastener.The ferrule 302 may use several techniques for fastening the lanyard 134and the pin assembly 304, including gripping, soldering, brazing,crimping, welding, or laser fusing, among other fastening techniques.The fastener provides a thin connection that maintains thecross-sectional profile of the pin assembly 304 and the lanyard 134.Thus, the pin assembly 304, the ferrule 302 and the lanyard 134 may beinserted through small holes in articles to secure the EAS tag 1 to thearticle, while causing no damage or minimal damage to the article.

After the lanyard 134 is passed through the article to be monitored, thepin assembly 304 is inserted into the aperture 124 to physically securethe EAS tag 1 to the article and to establish an electrical connectionthat engages an alarm system. According to one embodiment, the pin body306 is mechanically coupled within the EAS tag 1 by the clamp body 14.For example, the aperture 14C′ of the clamp body 14 engages thecircumferential groove 308 in the pin body 306 to mechanically securethe pin body 306. An intermediate spring contact 315 is provided toelectrically couple the pin body 306 to the printed circuit (“PC”) board110.

The EAS tag 1 may include several elements, such as a battery 112, apiezo transducer 152, the sensor 5, sensor shield 106, pin switch 122,spring contact 315, and locking member 6, among other elements. The EAStag 1 may include several features, such as apertures 115,116, batterycavity 113, and a piezo transducer cavity 114, among other features.Battery 112 fits into cavity 113 and a piezo transducer 152 fits intocavity 114. Both are used in conjunction with circuitry on PC board 110to form the alarm. The alarm can be configured so that battery 112 canbe placed into cavity 113 or cavity 114, and the piezo transducer can beplaced into the unused cavity.

Referring to FIG. 7, the intermediate spring contact 315 is mechanicallyand electrically coupled to the clamp body 14 and includes an aperture315A for mounting to the circular mount 21. The intermediate springcontact 315 therefore pivots about the circular mount 21. Theprojections 316 are configured to electrically couple the spring contact315 to the PC board 110. Thus, an electrical signal originating from thePC board 110 travels through the lanyard 134, the ferrule 302, the pinassembly 304, the clamp body 14, and the intermediate spring contact315, before returning to the PC board 110.

FIGS. 8 and 9 illustrate a first orientation and a second orientation,respectively, of the intermediate spring contact 315 relative to the PCboard 110. In the first orientation, the lanyard 134 is secured in theEAS tag 1 and the pin body 306 is locked in the aperture 14C′ of theclamp body 14. In the first orientation, the projections 316 provide anelectrical connection with the pad 805 to produce a signal placing theEAS tag 1 in an “armed” state. In the armed state, the EAS tag 1 maygenerate an alert, such as sounding an audible alarm, flashing an LED orother alert when the electrical contact is disconnected, such as bypulling the pin assembly 304 out of the EAS tag 1, cutting the lanyardor otherwise disconnecting the electrical contact.

In the second orientation, the clamp body 14 and the intermediate springcontact 315 are provided with a rotational force to release the pinassembly 306 from the aperture 14C′ of the clamp body 14. For example,the rotational force may be applied by the special arcuate probe 8. Whenthe intermediate spring contact 315 rotates about the mount 21, theprojections 316 contact pad 810 to produce a “reset” signal thatdeactivates the alarm system. In order to provide the system with timeto receive the reset signal, a time delay may be provided between whenthe electrical signal flowing through pad 805 is disrupted and when analert is generated. After entering the reset state, the EAS tag 1 willnot generate an alert, such as sounding an audible alarm, flashing anLED or other alert when the electrical contact is disconnected, such asby pulling the pin assembly 304 out of the EAS tag 1, cutting thelanyard or otherwise disconnecting the electrical contact.

According to one embodiment, a pin switch 122 may be provided to form asecond electrical connection with the pin body 306. Upon insertion intothe EAS tag 1, the pin body 306 abuts and moves the pin switch 122 toform an electrical contact on the PC board 110, thereby “arming” the EAStag 1. Once the EAS tag 1 is armed, if either the electrical signalflowing through the pad 805 is disrupted or the switch 122 are opened,then the EAS tag 1 may sound an alarm. If only the pin switch 122 wasused to “arm” the EAS tag 1, then the lanyard 135 could be cut and theEAS tag 1 would not alarm. Once armed, the EAS tag 1 may be disarmed orturned off by rotating the intermediate spring contact 315 about themount 21 to produce the “reset” signal by contacting the projections 316against contact pad 810. The EAS tag alarm switch logic is fullydescribed in FIG. 10.

FIG. 10 illustrates an electrical schematic of a self-alarming tag alarm1000 to prevent tag defeat. Tag alarm 1000 emits an alarm signal thatmay include an audible alarm, flashing light, an RF signal, or otheralarm signal, to a remote device. The alarm signal is different from analert signal that is emitted by the EAS system when the EAS tag 1 iscarried into an interrogation zone. Printed circuit (PC) board 110contains the circuitry for the tag alarm 1000, which emits the alarmsignal if the EAS tag 1 is detached from the monitored article by otherthan detacher probe 8.

The series of apertures 115 and 116 through the upper and lower taghousing members, respectively, cover the area adjacent both cavities 113and 114. Because the apertures cover the area adjacent cavities 113 and114, the apertures 115 and 116 cannot be used as a localized target todirect a probe to the piezo in an attempt to destroy or damage it. Aprobe forced directly into the piezo could damage or destroy the piezo,but a probe indiscriminately inserted into the EAS tag 1 could set offthe tag alarm.

Sensor shield 106 may be placed on one or both sides of sensor 5 toprevent one mode of defeat where a metal probe, screw driver, or thelike, is forced through upper or lower tag housing members 102 or 104,respectively, to damage or destroy sensor 5 or piezo transducer 152.Once sensor 5 or piezo transducer 152 is destroyed, the article to whichEAS tag 1 is attached can be moved through the interrogation zonewithout setting off the EAS alarm. Sensor shield 106 is preferably madeof a nonferrous metal such as stainless steel or other very hardmaterial that does not effect the operation of sensor 5, but which iscapable of making the insertion of a metal probe or the like to damagesensor 5 or piezo transducer 152 extremely difficult. The sensor shield106 may be placed in the upper tag housing member 302, for example.

The tag alarm 1000 may sound upon unauthorized removal of pin assembly304 from the EAS tag 1, disruption of the signal through theintermediate spring contact 315 or the pin switch 122, which are used toprovide alarming logic. Referring to FIG. 10, microprocessor 155 isconnected to piezo transducer 152, pin switch 122, intermediate springcontact switch 120, and battery 112. The microprocessor 154 generatesthe signal to drive piezo transducer 152, based upon the switch logic.The piezo transducer 152 may be driven at about 3 kHz steady, or toconserve battery life, can be pulsed, for example, at 1 Hz, or can befrequency modulated with a deviation of 250 Hz and a modulationfrequency of 4 Hz, or driven in a combination of modulation techniques.The piezo transducer 152 may be any small transducer that makes anaudible sound and that may be driven at relatively low power.

In addition to the switches described above, a magnet switch 130 may beconnected to microprocessor 154. One embodiment of the EAS tag 1includes a magneto-mechanical sensor 5. Magneto-mechanical sensorsinclude a magnetostrictive resonator that resonates at a preselectedfrequency when biased by a magnetic field. Magnetomechanical sensors arethus affected by a magnetic field. One defeat method involves placing arelatively strong magnet next to the EAS tag 1 so the resonator is nolonger biased correctly and no longer resonates at the desiredfrequency. If the tag does not resonate at the desired frequency, itwill not be detected when moved through an interrogation zone. The EAStag 1 may include a magnet switch 130, which is closed upon exposure toan externally applied magnetic field, thus alarming the EAS tag 1. Themagnet switch 130 can be any suitable magnet switch such as a reedswitch, or a wire segment with a free end positioned within an exposedwire loop, and which moves in an applied magnetic field touching theexposed wire loop to make contact and close the switch.

An LED 132 may be connected to microprocessor 154. When the EAS tag 1 isarmed, the LED 132 flashes to indicate that the EAS tag 1 is active. TheLED 132 can be configured to flash at a desired repetition rate, forexample at 3 seconds on and 3 seconds off. To conserve battery life, theon time for the LED 132 can be pulsed or cycled at a frequency that ishigher than that detectable to the human eye. Thus, during the time thatthe LED 132 is on, it will appear to be constant but will actually becycling on and off very rapidly. For example, the cycle frequency forthe on time should be greater than 50 Hz, such as 333 Hz. A flashing LED132 indicates that the EAS tag 1 is armed, and will alarm if tamperedwith, which provides additional deterrence to defeat attempts. Uponalarming, the repetition rate of 3 seconds on and 3 second off maychange. For example, the LED 132 may cycle at a faster repetition rate.When the EAS tag 1 is alarming, the response of the LED 132 may bevisually different than when tag EAS 1 is in the armed state. Thispermits easy location of an alarming EAS tag 1 in proximity to aplurality of armed tags that are not alarming.

The lanyard 134 is connected to microprocessor 154. During use, thelanyard 134 is attached around or through an opening in a portion of themonitored article and the pin assembly 304 is inserted into the aperture124. The end of the lanyard 134 with the pin assembly 304 can then beinserted into the aperture 124 and locked within the clamp body 14. Thelanyard 134 is electrically conductive. The microprocessor 154 detectsif the lanyard 134 is cut and generates an alarm.

FIG. 11 illustrates a block diagram of steps performed by themicroprocessor 154 for operating the EAS tag 1. The EAS tag 1 begins inthe unarmed state in step S1101. A determination is made in step S1103regarding whether the pin switch is closed. If the pin switch is closed,a determination is made regarding whether a current path is formedthrough the intermediate spring contact at step S1105. If the currentpath is formed, then the EAS tag 1 is armed at step S1107. Adetermination is made regarding whether the current is disrupted at stepS1109. If the current is disrupted, then a determination is made whethera reset signal is generated at step S1111. If a reset signal is notgenerated, then an alarm signal is generated at step S1113. If a resetsignal is generated, then the EAS tag is returned to the unarmed stateat step 1101 and an alarm is not generated. If the current is notdisrupted, then a determination is made regarding whether the magnetswitch is closed by an applied magnetic field at step S1115. If themagnet switch is closed, then the alarm signal is generated at stepS1113. If the magnetic switch is not closed, then the EAS tag isreturned to the armed state in step S1107. If the alarm is activated atstep S1113, then it may be turned off at step S1117.

The EAS tag 1 may be configured to have all of the tag defeat devicesand methods described herein or any combination thereof For example,decoy tags could be used where the LED 132 flashes to indicate the tagis armed, but the tag may not have an alarm, it may only have theflashing LED. A perpetrator will not know if the EAS tags include alarmor not, as they will appear identical to the EAS tags that are equippedwith alarms.

It is understood that the above-described arrangements are merelyillustrative of the many possible specific embodiments, which representapplications of the present invention.

In addition, unless mention was made above to the contrary, it should benoted that all of the accompanying drawings are not to scale.Significantly, this invention can be embodied in other specific formswithout departing from the spirit or essential attributes thereof, andaccordingly, reference should be had to the following claims, ratherthan to the foregoing specification, as indicating the scope of theinvention.

1. An electronic article surveillance (EAS) tag, comprising: a tag bodydefining an interior and having an opening leading into the interior; acircuit board disposed in the tag body interior; a lanyard having afirst end and a second end opposite the first end, the first end beingelectrically coupled to the circuit board; a pin body electricallycoupled to the second end of the lanyard, the pin body being insertableinto the tag body opening; a clamp disposed in the tag body interior,the clamp being arranged to receive the pin body; and a spring contactdisposed in the tag body, the spring contact electrically coupling theclamp and the circuit board to provide a current path for electricalsignals through the lanyard.
 2. The EAS tag according to claim 1,wherein the pin body has a circumferential groove and the clamp engagesthe circumferential groove.
 3. The EAS tag according to claim 1, whereinthe pin assembly includes one of a curvilinear shape or a linear shape.4. The EAS tag according to claim 1, further comprising: a pin assemblythat is mechanically and electrically coupled to the second end of thelanyard, the pin assembly comprising the pin body.
 5. The EAS tagaccording to claim 2, wherein the pin assembly and the lanyard have asubstantially equivalent cross-sectional profile.
 6. The EAS tagaccording to claim 1, further comprising a passage defined in the tagbody interior that provides a channel from an exterior of the tag bodyto the clamp.
 7. The EAS tag according to claim 1, wherein the tag bodyinterior includes a mount, the clamp includes a clamp aperture thatreceives the mount; and the spring contact includes a spring contactaperture that receives the mount, and wherein the clamp and the springcontact are configured to pivot on the mount.
 8. The EAS tag accordingto claim 7, wherein the circuit board includes a first pad and a secondpad, and wherein the spring contact includes a projection that iselectrically coupled to the first pad at a first position and iselectrically coupled to the second pad at a second position, and whereinthe spring contact pivots on the mount to move the projection betweenthe first position and the second position.
 9. A method of securing anelectronic article surveillance (EAS) tag to an article, the EAS tagincluding a tag body defining a tag body interior and an alarm disposedin a tag body interior, the EAS tag further including an electricallyconductive lanyard having a first end and a second end opposite thefirst end, the first end being electrically fixedly coupled to a circuitboard provided in the tag body interior and the second end being coupledto a pin body, the pin body being electrically couplable to the circuitboard, the tag body further housing a clamp to mechanically lock the pinbody at last partially inside the tag body, the alarm being electricallycoupled to the circuit board, the method comprising: attaching thelanyard to the article by one of inserting the lanyard through anopening in the article and wrapping the lanyard around at least aportion of the article; inserting the pin body into the tag bodyinterior; applying a force to the pin body to cause the pin body to lockinto the clamp in the tag body interior, the tag body interior furtherincluding a spring contact to electrically couple the clamp to thecircuit board to create a enable a current to flow from the circuitboard, through the lanyard, the clamp and the spring contact beforereturning to the circuit board.
 10. The method according to claim 9,further comprising disrupting the current path, the current pathdisruption causing the alarm to activate.
 11. The method according toclaim 10, wherein disrupting the current path includes at least one ofdisconnecting the second end of the lanyard from the clamp and cuttingthe lanyard.
 12. The method according to claim 10, further comprisingcausing the generation of a reset signal to deactivate the alarm. 13.The method according to claim 12, further comprising causing the springcontact to pivot to thereby generate the reset signal, the springcontact being electrically couplable with a reset connection on thecircuit board.
 14. An electronic article surveillance (EAS) tag,comprising: a tag body defining an interior and having: an openingleading into the interior; and a lanyard mounting structure in the tagbody interior; and a securing device coupled to the tag body, thesecuring device comprising: a lanyard having a first end and a secondend opposite the first end, the first end being coupled to the lanyardmounting structure; a fastener coupled to the second end of the lanyard;a pin assembly coupled to the fastener, the lanyard, the fastener andthe pin assembly having substantially equivalent cross-sectionalprofiles.
 15. The EAS tag according to claim 14, wherein the securingdevice is electrically conductive.
 16. The EAS tag according to claim14, wherein the pin assembly includes one of a curvilinear shape or alinear shape.
 17. The EAS tag according to claim 16, wherein the pinassembly includes a pin body having a circumferential groove.
 18. TheEAS tag according to claim 16, further comprising a clamp disposed inthe tag body interior, the clamp being arranged to receive the pin body.19. The EAS tag according to claim 18, wherein the clamp includes anaperture that receives the pin body and mechanically engages thecircumferential groove.
 20. The EAS tag according to claim 19, whereinthe aperture is configured to release the pin body.